Exploring Light Diffraction Phenomena

1. Phys 102 – Lecture 23 Diffraction

2. Today we will... • Learn about diffraction – bending of light by objects • Single slit interference • Circular aperture interference • Apply these concepts • Resolution of optical instruments • X-ray crystallography

3. Single slit interference? What happens when light passes through a small slit? Without diffraction With diffraction This is NOT what happens! Diffraction – the apparent bending of light around an object or aperture

4. Diffraction & Huygens’ principle Coherent, monochromatic light passes through one narrow slit Wavelets through slit travel different distances and can interfere! Where are the interference maxima and minima?

5. Single slit diffraction Consider waves from top and bottom ½ of slit of width a a/2 a At this angle, every wave from top ½ of slit interferes destructively with corresponding wave from bottom ½ N 2 1 θ r1 1’ N’ 2’ r1' Destructive: 1st minimum

6. Single slit diffraction Consider waves from ¼’s of slit a/4 N 2 a 1 At this angle, every wave from top ¼ of slit interferes destructively with corresponding wave from next ¼ N’ 2’ 1’ r1 r1' Destructive: 2nd minimum

7. Single slit diffraction minima Condition for sixths of slit to interfere destructively m = +2 a m = +1 m = –1 m = –2 In general, THIS FORMULA LOCATES MINIMA!! Note the maximum at m = 0, why?

8. ACT: CheckPoint 1 The width a of the slit in the screen is decreased m = +2 a m = +1 m = –1 m = –2 What happens to the light pattern on the screen? A. It gets wider B. Stays the same C. It gets narrower

9. ACT: Wide double slits Consider a double slit where the slit width a is not negligible. The separation d between slits is such that d = 3a. a d θ At an angle θ where d sin θ = 3λ, what do you see on the screen? A. A maximum B. A minimum C. In between

10. Diffraction in 2D Single slit Square aperture Hexagonal aperture Circular aperture CheckPoint 2

11. Diffraction from circular aperture 1st diffraction minimum Central maximum D θ1 Maxima and minima will be a series of bright and dark rings on screen

12. Resolving power Demo: Resolving Power θobj θobj Light through aperture (of eye, camera, microscope, telescope, etc.) creates diffraction pattern θobj θmin θmin θmin Larger spacing Not resolved θobj θmin Just resolved Two objects are resolved only when: “Diffraction limit”

13. Calculation: microscope resolution θmin A microscope objective has an aperture size D = 6.8 mm, and a focal length f = 4 mm. What is the closest distance two green light sources (λ = 530 nm) can be to resolve them? D D dobj Use small angle approximation: f Want: θobj Ultimate limit to resolution:

14. ACT: CheckPoint 3 You are on a distant planet with binary suns. You decide to view them by building a pinhole camera. Light from both suns shines through the hole, but you can only see one spot on a screen. You should make the pinhole ________ A. Larger B. Smaller

15. ACT: Rectangular slit A goat has a rectangular shaped pupil, with the long axis along the horizontal. In principle, in which direction should a goat’s eye have higher resolution? A. Horizontal B. Vertical

16. Diffraction from a crystal EM waves of short wavelength scatters off of atoms d If there is more than one atom, scattered waves can interfere Crystals – periodic arrangements of atoms – create same interference pattern as diffraction grating!

17. ACT: Crystal diffraction In a NaCl crystal, the spacing between atoms is 0.282 nm. Which of the following wavelengths could be used to see a clear diffraction pattern? 0.282 nm A. λ = 0.1 nm B. λ = 1 nm C. λ = 10 nm

18. X-ray crystallography Given X-ray wavelength λ, diffraction angles θ provide information about distance d between atoms in crystal θ “Photo 51” Rosalind Franklin Crystalline fiber of DNA As long as λ < d, small features lead to large θ. BUT need regular ordering of atoms – i.e. a crystal!

19. Diffraction pattern of DNA • Features of pattern: • Layer lines • Outer diamond • Cross pattern • Missing 4th layer line 2 3 1 4 “Photograph 51” – Rosalind Franklin

20. Layer lines & diamond pattern What features in DNA generate layer lines and diamond pattern? DNA bases every P/10 P/10= 0.34 nm P = 3.4 nm θ m = +5 +3 +2 +1 –1 –2 –3 Helix repeats every P –5 Note that large (small) distances diffract to small (large) angles

21. Cross pattern Why does DNA diffraction generate cross pattern? Slit pattern P = 3.4 nm Strands are tilted at an angle Interference pattern Key to discovery of helix structure Light diffracted  to slit

22. ACT: DNA cross pattern You discover a new structure of DNA in which the diffraction pattern is the same as the “normal” DNA in every respect EXCEPT that the cross makes a more acute angle α New form of DNA “Normal” DNA Δθ Δθ α α Which statement regarding the new DNA structure must be true? A. It cannot be a helix B. The helix repeat distance P must be different C. The helix tilt angle must be different

23. Missing 4th layer Why is there no interference maximum at m = 4? 3P/8= 1.3 nm “Missing order” θ4 m = +4 Two DNA helices shifted by 3P/8 (“minor groove”) m = –4 Key to discovery of double helix Waves from helix 1 and 2 interfere destructively!

24. Summary of today’s lecture • Single-slit diffraction • Interference minima: • Circular aperture diffraction • First interference minimum: • Resolution in optical instruments • Angle subtended by objects ≥ angle of first diffraction minimum • X-ray diffraction • Small distances -> large diffraction angles